Current Stem Cell Research & Therapy - Volume 12, Issue 3, 2017

Acute renal failure (ARF) is a syndrome of abrupt decline in renal function induced by a number of different insults. In clinic, the common etiology for ARF is ischemia-reperfusion injury (IRI). The pathophysiological process of renal IRI is complex, there is no good treatment. Stem cell therapy is a new and promising treatment for renal IRI. Mesenchymal stem cells (MSCs) have the ability to differentiate into tissues of mesodermal lineages. MSCs are under intensive study as potential therapeutic strategy for renal IRI. MSCs have been investigated with immunomodulatory, anti-inflammatory and tissue repair properties which could attenuate ischemic injury and accelerate the regeneration process in the condition of renal IRI. Moreover, the MSCs have the ability to migrate to the injury sites and to stimulate repair by paracrine mechanisms rather by differentiating into the injured cells. Here we review the latest information on MSCs, their biological characteristics, including their therapeutic perspectives, and envisage their putative role in renal ischaemic conditioning.

With the development of chemotherapy and hematopoietic stem cell transplantation (HSCT), the prognosis of leukemia patients has been improved greatly in the past few decades. However, relapsed and refractory leukemia is still the major cause of mortality in leukemia patients. Besides, advancing age, poor performance status and severe co-morbidities limit the applicability of cytotoxic chemotherapy in certain groups of leukemia patients. Novel agents including nucleoside analogs, kinase inhibitors targeting oncoproteins and monoclonal antibodies are under investigation for the management of leukemia. Nevertheless, the outcome remains disappointing. Since immune system plays an important role in eradicating tumor cells, a lot of studies have been conducted in the administration of cytotherapy of immune cells as an alternative method when chemotherapy and transplantation fail to cure the disease, including usage of natural killer (NK) cells, cytokine-induced killer (CIK) cells, donor lymphocyte infusion (DLI), chimeric antigen receptor (CAR)-modified T cells, dendritic cell (DC)-based vaccine and antigen-specific cytotoxic T lymphocytes (CTL). Due to overexpression of several leukemia associated antigens (LAA), leukemic cells are potentially suitable for cellular therapy approach. Here we review the recent literature regarding the different types of cytotherapy against leukemia, and talk about both efficacy and adverse effects related to the strategy.

Mesenchymal stem cells (MSCs) are stromal origin cells with multilineage differentiation capacity. The immunoregulatory properties of MSCs can be interfered effectively by cytokines. Cytokines, produced by a broad range of cells, act at the systemic level to influence biological phenomena such as inflammation, wound healing, organogenesis and oncogenesis. Cytokines also play vital roles in the differentiation of MSCs into several cell lineages. This review summarizes on how cytokines can affect MSCs differentiation and their relative signaling pathways, which may serve to understand the possible underlying mechanisms. Also, this review reveals the potential clinical use of MSCs as promising therapeutic agents due to their special characteristics such as multipotent differentiation, immunomodulatory properties, and selfrestoration.

Stem cell research is a rapidly developing field that offers effective treatment for a variety of malignant and non-malignant diseases. Stem cell is a regenerative medicine associated with the replacement, repair, and restoration of injured tissue. Stem cell research is a promising field having maximum therapeutic potential. Cancer stem cells (CSCs) are the cells within the tumor that posses capacity of selfrenewal and have a root cause for the failure of traditional therapies leading to re-occurrence of cancer. CSCs have been identified in blood, breast, brain, and colon cancer. Traditional therapies target only fast growing tumor mass, but not slow-dividing cancer stem cells. It has been shown that embryonic pathways such as Wnt, Hedgehog and Notch, control self-renewal capacity and involved in cancer stem cell maintenance. Targeting of these pathways may be effective in eradicating cancer stem cells and preventing chemotherapy and radiotherapy resistance. Targeting CSCs has become one of the most effective approaches to improve the cancer survival by eradicating the main root cause of cancer. The present review will address, in brief, the importance of cancer stem cells in targeting cancer as better and effective treatment along with a concluding outlook on the scope and challenges in the implication of cancer stem cells in translational oncology.

Orthopaedic surgery lends itself well to advances in technology. An area of interest and ongoing research is that of the production of scaffolds for use in trauma and elective surgery. 3D printing provides unprecedented accuracy in terms of micro- and macro-structure and geometry for scaffold production. It can also be utilised to construct scaffolds of a variety of different materials and more recently has allowed for the construction of bio-implants which recapitulate bone and cartilage tissue. This review seeks to look at the various methods of 3DP, the materials used, elements of functionality and design, as well as modifications to increase the biomechanics and bioactivity of 3DP scaffolds.

The extracellular matrix is produced by the resident cells in tissues and organs, and secreted into the surrounding medium to provide biophysical and biochemical support to the surrounding cells due to its content of diverse bioactive molecules. Recently, the extracellular matrix has been used as a promising approach for tissue engineering. Emerging studies demonstrate that extracellular matrix scaffolds are able to create a favorable regenerative microenvironment, promote tissue-specific remodeling, and act as an inductive template for the repair and functional reconstruction of skin, bone, nerve, heart, lung, liver, kidney, small intestine, and other organs. In the current review, we will provide a critical overview of the structure and function of various types of extracellular matrix, the construction of three-dimensional extracellular matrix scaffolds, and their tissue engineering applications, with a focus on translation of these novel tissue engineered products to the clinic. We will also present an outlook on future perspectives of the extracellular matrix in tissue engineering and regenerative medicine.

Stem cells (SCs) are capable of self-renewal and multilineage differentiation. Human mesenchymal stem cells (MSCs) and haematopoietic stem cells (HSCs) which can be obtained from multiple sources, are suitable for application in regenerative medicine and transplant therapy. The aim of this review is to evaluate the potential of genomic and proteomic profiling analysis to identify the differentiation of MSCs and HSCs towards osteoblast and odontoblast lineages. In vitro differentiation towards both of these lineages can be induced using similar differentiation factors. Gene profiling cannot be utilised to confirm the lineages of these two types of differentiated cells. Differentiated cells of both lineages express most of the same markers. Most researchers have detected the expression of genes such as ALP, OCN, OPN, BMP2 and RUNX2 in osteoblasts and the expression of the DSPP gene in odontoblasts. Based on their cell-type specific protein profiles, various proteins are differentially expressed by osteoblasts and odontoblasts, except for vimentin and heterogeneous nuclear ribonucleoprotein C, which are expressed in both cell types, and LOXL2 protein, which is expressed only in odontoblasts.

Mechanical stimulation is a key factor in articular cartilage generation and maintenance. Bioreactor systems have been designed and built in order to deliver specific types of mechanical stimulation. The focus has been twofold, applying a type of preconditioning in order to stimulate cell differentiation, and to simulate in vivo conditions in order to gain further insight into how cells respond to different stimulatory patterns. Due to the complex forces at work within joints, it is difficult to simulate mechanical conditions using a bioreactor. The aim of this review is to gain a deeper understanding of the complexities of mechanical stimulation protocols by comparing those employed in bioreactors in the context of tissue engineering for articular cartilage, and to consider their effects on cultured cells. Allied and Complementary Medicine 1985 to 2016, Ovid MEDLINE[R] 1946 to 2016, and Embase 1974 to 2016 were searched using key terms. Results were subject to inclusion and exclusion criteria, key findings summarised into a table and subsequently discussed. Based on this review it is overwhelmingly clear that mechanical stimulation leads to increased chondrogenic properties in the context of bioreactor articular cartilage tissue engineering using human cells. However, given the variability and lack of controlled factors between research articles, results are difficult to compare, and a standardised method of evaluating stimulation protocols proved challenging. With improved standardisation in mechanical stimulation protocol reporting, bioreactor design and building processes, along with a better understanding of joint behaviours, we hope to perform a meta-analysis on stimulation protocols and methods.